Disinfecting cap

ABSTRACT

A device for cleaning medical implements is disclosed, in particular a device for cleaning vascular or other fluid access sites. The device includes a cap having an opening to receive an access site. The cap may be used in the following manner: A healthcare worker may, with gloved hands, open the cap packaging and place the cap over the port of a medical implement to be cleaned. The healthcare worker may wipe the site by either applying a turning motion or by simply pushing the cap onto the port. The cap could then remain secured in place by threads other mechanisms. A cap in place on a medical implement may be a positive indication that a desired site of the medical implement is clean. The cap may include a disinfecting substance.

RELATED APPLICATIONS

This application claims priority to and the benefit of the followingU.S. Provisional Application Nos. 62/208,243, entitled “DisinfectingCap,” filed Aug. 21, 2015; 62/208,364, entitled “Disinfecting Cap,”filed Aug. 21, 2015; 62/208,213, entitled “Disinfecting Cap with Valve,”filed Aug. 21, 2015; and 62/216,650, entitled “Disinfecting Cap withFluid Reservoir,” filed Sep. 10, 2015. The contents of each of theseapplications are herein incorporated by reference in their entirety.

BACKGROUND

Within the medical field, and in particular the area of infusion offluids or aspiration of fluids to or from a patient, there is a need toprevent the transmission of pathogens into or onto a patient from apotentially contaminated surface of a medical implement. Such pathogensinclude microorganisms such as bacteria and viruses. The transmission ofpathogens into a patient may result in an infection that could be lifethreatening. Common sites for such transmissions are found at access“sites” of medical implements such as a luer port, vial, needle freevalve, or an injection port of a vessel, tubing, or catheter. Evennon-intrusive medical implements such as stethoscopes or otoscopes cantransmit pathogens to a patient.

Accordingly, a need exists for an apparatus and technique for cleaning asite on a medical implement prior to contact with a patient.

BRIEF DESCRIPTION OF THE DRAWINGS

Advantages of the invention will become apparent upon reading thefollowing detailed description and upon reference to the drawings.

FIG. 1 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 2 shows an end view of the disinfecting cap of FIG. 1.

FIG. 3 shows a cross-sectional view along line A-A of the disinfectingcap of FIGS. 1-2.

FIG. 4 shows a perspective view of the disinfecting cap of FIGS. 1-3attached to a threaded female port of a Y-site.

FIG. 5 shows a side view of the cap and Y-site of FIG. 4.

FIG. 6 shows a side view of a cap and Y-site in accordance withembodiments of the invention.

FIG. 7 shows a perspective view of a cap in accordance with embodimentsof the invention.

FIG. 8 shows a side view of the cap of FIG. 7.

FIG. 9 shows a perspective view of the disinfecting cap of FIGS. 7-8attached to a threaded female port of a Y-site.

FIG. 10 shows a perspective view of a cap in accordance with embodimentsof the invention.

FIG. 11 shows another perspective view of the cap of FIG. 10.

FIG. 12 shows a side view of the cap of FIGS. 10-11.

FIG. 13 shows a view of the proximal end of the cap of FIGS. 10-11.

FIG. 14 shows a perspective view of a cap in accordance with embodimentsof the invention.

FIG. 15 shows a side view of the cap of FIG. 14.

FIG. 16 shows a cross-sectional view of a cap in accordance withembodiments of the invention.

FIG. 17 shows a perspective view of the cap of FIG. 16.

FIG. 18 shows a perspective view of a cap having a retention mechanismin accordance with embodiments of the invention.

FIG. 19 shows a view of the proximal end of the cap of FIG. 18.

FIG. 20 shows a perspective view of a cap having a further retentionmechanism in accordance with embodiments of the invention.

FIG. 21 shows a view of the proximal end of the cap of FIG. 20.

FIG. 22 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 23 shows a second perspective view of the disinfecting cap of FIG.22.

FIG. 24 shows a view of the proximal end of the cap of FIG. 22.

FIG. 25 shows a cross-sectional view along line B-B of the disinfectingcap of FIG. 22.

FIG. 26 shows a side view of the cap of FIG. 22.

FIG. 27 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 28 shows a view of the proximal end of the cap of FIG. 22.

FIG. 29 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 30 shows a second perspective view of the disinfecting cap of FIG.29.

FIG. 31 shows a view of the proximal end of the cap of FIG. 29.

FIG. 32 shows a side view of the disinfecting cap of FIG. 29.

FIG. 33 shows a side view of the disinfecting cap of FIG. 29 attached toa threaded female port of a Y-site.

FIG. 34 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 35 shows a view of the proximal end of the cap of FIG. 34.

FIG. 36 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 37 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 38 shows a top view of the disinfecting cap of FIG. 37.

FIG. 39 shows a side view of the disinfecting cap of FIG. 37.

FIG. 40 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 41 shows a view of the proximal end of the cap of FIG. 40.

FIG. 42 shows a side view of the cap of FIG. 40.

FIG. 43 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIGS. 44A and 44B show a bottom view of the disinfecting cap of FIG. 43.

FIG. 45 shows a cross-sectional view of the disinfecting cap of FIG. 43.

FIG. 46 shows a side view of disinfecting cap in accordance withembodiments of the invention.

FIG. 47 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 48 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 49 shows a side view of the disinfecting cap of FIG. 48.

FIG. 50 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 51 shows a second perspective view of the disinfecting cap of FIG.50.

FIG. 52 shows a view of the proximal end of the cap of FIG. 50.

FIG. 53 shows a cross-sectional view along line C-C of the disinfectingcap of FIG. 50.

FIG. 54 shows a side view of the cap of FIG. 50.

FIG. 55 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 56 shows a view of the proximal end of the cap of FIG. 55.

FIG. 57 shows an end view of the cap of FIG. 55.

FIG. 58 shows a perspective view of disinfecting cap in accordance withembodiments of the invention.

FIG. 59 shows a view of the proximal end of the cap of FIG. 58.

FIG. 60 shows a cross-sectional view along line D-D of the disinfectingcap of FIG. 58 along with a cross-sectional view of a Y-site having athreaded female port.

FIG. 61 shows a perspective view of disinfecting cap in accordance withembodiments of the cap shown in FIG. 58 at a subsequent stage of use.

FIG. 62 shows a cross-sectional view along line D-D of the disinfectingcap of FIG. 61 along with a cross-sectional view of a Y-site having athreaded female port.

FIG. 63 shows a perspective view of disinfecting cap in accordance withembodiments of the cap shown in FIG. 61 at a subsequent stage of use.

FIG. 64 shows a cross-sectional view along line D-D of the disinfectingcap of FIG. 63 along with a cross-sectional view of a Y-site having athreaded female port.

FIG. 65 shows a perspective view of disinfecting cap in accordance withembodiments of the cap shown in FIG. 63 at a subsequent stage of use.

FIG. 66 shows a cross-sectional view along line D-D of the disinfectingcap of FIG. 67 along with a cross-sectional view of a Y-site having athreaded female port.

While the invention is susceptible to various modifications andalternative forms, specific embodiments have been shown by way ofexample in the drawings and will be described in detail herein. Itshould be understood, however, that the invention is not intended to belimited to the particular forms disclosed. Rather, the invention is tocover all modifications, equivalents, and alternatives falling withinthe spirit and scope of the invention.

DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Embodiments of the invention are now described in detail. Referring tothe drawings, like numbers indicate like parts throughout the views. Asused in the description herein and throughout the claims, the followingterms take the meanings explicitly associated herein, unless the contextclearly dictates otherwise: the meaning of “a,” “an,” and “the” includesplural reference, the meaning of “in” includes “in” and “on.” Relationalterms such as first and second, top and bottom, forward and rearward,and the like may be used solely to distinguish one entity or action fromanother entity or action without necessarily requiring or implying anyactual such relationship, direction or order between such entities oractions.

The terms “proximal” and “distal” are used throughout this applicationwhen describing various embodiments. These terms are not intended to belimiting and are merely provided for ease of maintaining a consistentorientation when describing various embodiments. As used herein,proximal refers to the direction generally closer to the patient and/ormedical device to be cleaned and distal refers to the directiongenerally farther from the patient and/or medical device to be cleaned.

This application provides a description of various implementations andembodiments of a device for cleaning medical implements, in particular adevice for cleaning vascular or other fluid access sites. Variousembodiments of the invention include a cap having an opening to receivean access site. Throughout this application illustrative embodimentsrefer to use of a cap to engage with a “port” as an example of such anaccess site. One of skill in the art would understand that the inventionmay also be used in conjunction with other access sites or other medicaldevices without access sites.

The following is a non-limiting example of how such a cap may be used bya healthcare worker: the healthcare worker may, with gloved hands, openthe cap packaging and place the cap over the port of a medical implementto be cleaned. In certain embodiments, the healthcare worker may wipethe site by either applying a turning motion or by simply pushing thecap onto the port. The cap could then remain secured in place by threadsother mechanisms described herein. A cap in place on a medical implementmay be a positive indication that a desired site of the medicalimplement is clean. A vibrant color or other indicia may be used toallow instant visualization of a cap's presence from a door or hallway.

Embodiments of the cap described herein may include a disinfectingsubstance, such as a solution of a suitable microbiocide or germicide.The disinfecting substance can include an anti-bacterial disinfectant ofany suitable type and suitable amount depending upon the size andstructure of the cap. For example, in some embodiments the disinfectingsubstance may be an aqueous solution including about two percent (2%)chlorhexidine gluconate (chlorhexidine solution, “CHG”). In otherembodiments, a solution including about 70 percent (70%) isopropylalcohol (“IPA”) in an aqueous solution is included in the disinfectingsubstance. In yet another embodiment, a solution including about 70percent (70%) IPA and about two percent (2%) CHG in an aqueous solutionis included in the disinfecting substance. In the latter solution, it isrecognized that the concentration of IPA can vary from about 60 percent(60%) to about 90 percent (90%) and the concentration of CHG can varyfrom about one percent (1%) to about five percent (5%), in oneembodiment.

Other suitable solution compositions and concentrations are alsopossible. For instance, povidone iodine, polyhexanide (polyhexamethylenebiguanide, “PHMB”), benzalkonium chloride (“BAC”), chlorxylenol (“PCMX”)or hydrogen peroxide solutions can be included in the disinfectingsubstance of further embodiments. Throughout this disclosure, referenceto one or more of these disinfecting substances in relation to a capembodiment should be understood to disclose the use of any otherappropriate disinfecting substance as disclosed herein or as would beunderstood by one of ordinary skill in the art. In addition, embodimentsof the disinfecting substance may be in a liquid or a gel form.

In various embodiments of the invention described herein, the port comesin contact with the disinfecting substance in liquid or gel form, orwith an absorbent material infused with the disinfecting substance.However, it may not be necessary for the surface of the port to contactthe liquid or gel disinfecting substance. For example, if IPA is used aspart of a disinfecting solution, IPA vapors trapped within the cap mayact as a disinfectant for the port without requiring contact between theliquid solution and the site being cleaned.

Various materials may be used to manufacture the cap embodimentsdescribed herein. Appropriate materials may include polyurethane (“PU”),polypropylene (“PP”), thermoplastic elastomer (“TPE”), Sanoprene orother materials as would be understood by one of ordinary skill in theart. Various embodiments described herein recite the use of particularmaterials, but one of ordinary skill would understand that otherappropriate materials could be substituted for the disclosed material.

Various embodiments also describe the use of foam material. Such foammay be formed of polyurethane (“PU”) or another appropriate absorbentmaterial. Alternatively, other absorbent materials may be used in placeof foam, including for example, a felted non-woven or other fibrousmaterials.

FIGS. 1-3 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 1002 is molded from PP. The capincludes an opening 1004 with a peripheral lip 1006. The opening 1004provides access to a first cavity 1008 and a second cavity of smallerdiameter 1010 extends from a base 1012 of the first cavity 1008. The capmay include ribs 1022 formed on an exterior surface to provide easierhandling and twisting of the cap by a healthcare worker.

A foam ring 1014 is positioned within the first cavity 1008. The foamring 1014 has a central bore 1016 extending through the ring. Thecentral bore 1016 has a diameter that is smaller than the diameter ofthe second cavity 1010. The foam ring 1014 includes notches 1024 formedat intervals around the periphery of the ring, and the ring may beinfused with a disinfecting solution. The second cavity 1010 includesthreads 1020 formed on the inside diameter 1018 of the cavity.

As shown in FIGS. 4-5, the cap 1002 may be attached to the threadedfemale port of a Y-site 1026. The female port is inserted through thebore 1016 of the foam ring 1014. The foam ring thereby wipes the outsidesurface of the port and applies a disinfecting solution. Threads 1028formed on an outside diameter of the female port 1026 engage with theinterior threads 1020 of the second cavity 1010, securing the cap to theport.

As shown in FIG. 5, the second cavity 1010 may have a depth such thatthe female port or its threads bottom out in the cavity before the cap1002 contacts other portions of the Y-site. Alternatively, as shown inFIG. 6, the second cavity 1010 may be deeper such that the cap contactsthe second port 1030 of the Y-site or such that a shoulder 1032 of thefemale port contacts the base 1012 of the first cavity surrounding thediameter of the second cavity.

FIGS. 7-9 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 1102 may be molded from PP oranother appropriate material. The cap includes an open proximal end 1104and a closed distal end 1106. The cap 1102 may include ribs 1126 formedon an exterior surface to provide easier handling and twisting of thecap by a healthcare worker. The ribs may extend parallel to a centralaxis of the cap, as illustrated, or may have another configuration.Alternatively, other knurling, texturing, finger shaped or grip elementsmay be provided.

The proximal end has an opening 1108 that provides access to a cavity1110. The cavity 1110 has a proximal section 1112 and a distal section1114. The distal section 1114 may include threads 1116 formed on itsinterior diameter. A foam ring 1118 is inserted into the proximal cavitysection 1112. The foam ring 1118 has a central bore 1120 extendingthrough the ring. The ring 1118 extends a distance into the cavity 1110,but stops short of the threads 1116. The ring may be infused with adisinfecting solution.

As shown in FIG. 9, the cap 1102 may be attached to the threaded femaleport of a Y-site 1122. The female port of the Y-site is inserted throughthe bore 1120 of the foam ring 1118. The foam ring thereby wipes theoutside surface of the port and applies a disinfecting solution. Threads1124 formed on an outside diameter of the female port 1122 engage withthe interior threads 1116 of the distal cavity 1114, securing the cap tothe port.

FIGS. 10-13 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 1202 may be molded from PP oranother appropriate material. The cap includes an open proximal end 1204and a closed distal end 1206. The cap 1202 may include ribs 1226 formedon an exterior surface to provide easier handling and twisting of thecap by a healthcare worker. The ribs may extend parallel to a centralaxis of the cap, as illustrated, or may have another configuration.Alternatively, other knurling, texturing, finger shaped or grip elementsmay be provided.

The proximal end has an opening 1208 that provides access to a cavity1210. The cavity 1210 includes a generally cylindrical interior surface1212. Though, the interior surface may be a conical section such thatthe diameter is larger adjacent to the opening 1208 than it is at theclosed, distal end 1214 of the cavity. The interior surface 1212 isdivided into sections, with each section encompassing at least a portionof the cylindrical surface. The sections include one or more foamsections 1216 and one or more thread sections 1218. Slots 1228 areformed in the foam sections 1218. The slots 1228 may extend generallyparallel to a central axis of the cap.

Foam pieces 1230 are inserted into the cavity 1208 along foam sections1216 of the interior surface. The foam pieces extend around thecircumference of the cavity along the foam sections thereby forming abroken ring extending around at least a portion of the cavity interiorcircumference. A finger 1232 formed on an outer surface of each foampiece engages the slot 1228 and serves to hold the foam piece in place.The foam piece may be formed in a pre-curved manner or may take on acurved shape as a result of being installed against the curvedcircumference of the cavity. The foam piece may be infused with adisinfecting solution.

Threads 1234 are formed on the interior circumference of the threadsections 1218. The cap 1202 may be attached to the threaded female portof a Y-site (not shown). The female port of the Y-site is insertedthrough into the cavity 1208, and threads formed on an outside diameterof the female port engage with the interior threads 1234 of the distalcavity, securing the cap to the port. As the port is threaded into thecavity, the surface of the port passes over the foam pieces therebywiping the outside surface of the port and applying a disinfectingsolution.

FIGS. 14-15 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 1302 may be molded from PP oranother appropriate material. The cap includes an open proximal end 1304and a closed distal end 1306. The cap 1302 may include ribs 1326 formedon an exterior surface to provide easier handling and twisting of thecap by a healthcare worker. The ribs may extend parallel to a centralaxis of the cap, as illustrated, or may have another configuration.Alternatively, other knurling, texturing, finger shaped or grip elementsmay be provided.

The proximal end has an opening 1308 that provides access to a cavity1310. The cavity 1310 includes a generally cylindrical interior surface1312. Though, the interior surface may be a conical section such thatthe diameter is larger adjacent to the opening 1308 than it is at theclosed, distal end 1306 of the cavity. Threads 1316 are formed on thecavity interior surface 1312 and spaced some distance from the distalend 1306 of the cap.

A seal 1318 is positioned across the opening 1308 of the cavity 1310.The seal may be positioned adjacent to the proximal end 1304 of thecavity or may be spaced some distance into the cavity, leaving a space1320 between the seal and the cap end. The space 1322 within the cavitythat is enclosed by the seal 1318 may be at least partially filed withIPA. The seal may include perforations 1324, score lines or otherfeatures to aid in fracturing the seal.

The cap 1302 may be attached to the threaded female port of a Y-site(not shown). The female port of the Y-site is inserted through into thecavity 1308, and threads formed on an outside diameter of the femaleport engage with the interior threads 1316 of the cavity, securing thecap to the port. As force is applied to the cap to engage the port, theperforated seal breaks away under pressure from the port. The portsurfaces are thereby exposed to liquid or vapor IPA.

FIGS. 16-17 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 1402 may be formed of PP oranother plastic. The cap includes side a generally cylindrical sidewall1404. The cap includes an open proximal end 1406 and a closed distal end1408 and encompasses a cavity 1410. The cap 1402 may include ribs (notshown) formed on an exterior surface to provide easier handling andtwisting of the cap by a healthcare worker. The ribs may extend parallelto a central axis of the cap, as illustrated in other embodiments, ormay have another configuration. Alternatively, other knurling,texturing, finger shaped or grip elements may be provided.

The cap further includes a diaphragm valve 1414 that covers the open end1406 of the cavity 1410. The valve covers a proximal end 1418 ofsidewall 1404 as well as the open end 1416 of the cavity 1410. A portion1422 of the diaphragm valve 1414 may extend beyond the opening along anoutside surface 1420 of sidewall 1404. The valve may be molded over thesides and open end of the cap. The diaphragm valve includes a slit 1424.A female port or other access site is pushed through the slit 1424 intothe cavity 1410. The diaphragm valve secures the end of the port in thecavity once the port passes through the slit.

A portion of the cavity 1410 may be filled with IPA or anotherdisinfecting substance in liquid or gel form. Alternatively, at least aportion of the cavity may be filled with a foam, such as an open cell PUfoam 1426. The foam may be infused with a disinfecting substance.

FIGS. 18-19 show an illustrative disinfecting cap having a retentionmechanism in accordance with embodiments of the invention. Variousembodiments of the invention as described in this application make useof threads formed on the outside of the site to be disinfected in orderto secure the cap to the site. However, the present invention alsocontemplates the use of alternative securement mechanisms asillustrated, for example, in FIGS. 18-19. The cap 1502 an open proximalend 1504 and a closed distal end 1506. The cap 1502 may include ribs1526 or other grip elements. The proximal end has an opening 1508 thatprovides access to a cavity 1510. The cavity 1510 includes a generallycylindrical interior surface 1512. Though, the interior surface may be aconical section such that the diameter is larger adjacent to the opening1508 than it is at the closed, distal end 1504 of the cavity.

Adjacent the opening 1508, the interior surface includes a series ofstepped counterbores 1514, 1516, 1518. Each successive counterbore has asmall diameter than the previous. Accordingly, as illustrated in FIG.18, the proximal counterbore 1514 adjacent to the opening has a firstdiameter, the next counterbore 1516 has a second small diameter and soon until the diameter of the interior surface 1512 is reached. Theillustrative embodiment shows three different counterbores, but more orfewer could be used.

The counterbores 1514, 1516, 1518 are sized to engage a thread, shoulderor other portion of the site with a friction fit. Alternatively, thecounterbores may provide clearance for a shoulder of the site so thatinterior surface 1512 may have an appropriate diameter to engage thethreads of a port with a friction fit.

FIGS. 20-21 show an illustrative disinfecting cap having an alternativeretention mechanism in accordance with embodiments of the invention. Thecap 1602 an open proximal end 1604 and a closed distal end 1606. The cap1602 may include ribs 1626 or other grip elements. The proximal end hasan opening 1608 that provides access to a cavity 1610. The cavity 1610includes a generally cylindrical interior surface 1612. Though, theinterior surface may be a conical section such that the diameter islarger adjacent to the opening 1608 than it is at the closed, distal end1604 of the cavity.

Retention elements 1614 extend from the interior surface 1612. Asillustrated in FIGS. 20-21, these elements are arranged in three columns1616 a, 1616 b, 1616 c spaced evenly around the interior surface.Though, more or fewer may be used. Within each column, a series ofretention elements 1614 a, 1614 b, 1614 c extends longitudinally intothe cavity 1610 along the interior surface 1612. Arranged in thismanner, the retention elements engage with the threads or other featuresof the port to be cleaned and retain the cap on the port. I

In various embodiments, the retention elements may be formed in aresilient manner such that the cap can be pushed onto the port. As thethreads of the port are pushed past each retention element, that elementallows the thread to pass and then rebounds into a position in which theretention element engages the thread and retains the cap. Alternatively,the cap may be screwed onto the port such that the retention elementsengage the threads.

The exemplary embodiment discussed herein contemplates arranging theretention elements 1614 in a certain pattern, particularly in equallycolumns of retaining elements. However, one of ordinary skill in the artwould understand that the retaining elements could be arrange in anyother possible patterns, including, among others, in a spiral pattern ora spaced matrix.

FIGS. 22-25 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 1702 is molded from PU and may bereaction injection molded from PU foam into the final shape. The moldedfoam 1740 may include a skin 1742 that is resistant to IPA or otherdisinfecting solutions. The cap includes an open proximal end 1704 and aclosed distal end 1706. The cap 1702 may include ribs 1726 formed on anexterior surface to provide easier handling and twisting of the cap by ahealthcare worker. The ribs may extend parallel to a central axis of thecap, as illustrated, or may have another configuration. Alternatively,other knurling, texturing, finger shaped or grip elements may beprovided.

The proximal end has an opening 1708 that provides access to a maincavity 1710. The cavity 1710 has a generally cylindrical sidewall 1712and distal or bottom surface 1714. Threads 1716 may be formed on thesidewall in order to engage with the threads of a site to be cleaned andto retain the cap on the site. The cylindrical sidewall may have aconstant diameter along a longitudinal axis of the cap or the diametermay increase along the longitudinal axis such that the diameter of thesidewall is greater at the distal end than the diameter of the sidewallat the proximal end at or near the bottom surface 1714 in oneembodiment. In another embodiment the diameter may decrease along thelongitudinal axis such that the diameter of the sidewall is smaller atthe distal end than the diameter of the sidewall at the proximal end ator near the bottom surface 1714.

One or more depressions, cavities or holes 1718 are formed extendinginto the cap from the distal surface 1714 of the cavity 1710. Theseholes 1718 are at least partially filled with and serve as reservoirs toretain a disinfecting solution such as liquid or gel ISA. When insertedinto the cap, the end surface of the site may come in contact with thedistal surface 1714 of the cavity 1710 such that the site is wetted bythe disinfecting solution, or the surface of the site may remain spacedfrom the distal surface such that disinfecting is provided bydisinfecting solution vapor contained within the cap.

The cap 1702 may include a peelable lid 1720 that is sealed to the skin1742 of the cap in order to retain the disinfecting solution within thecap cavity 1710, thereby preventing the disinfecting solution fromleaking or evaporating out from the cap 1702.

The holes 1718 may be generally cylindrical in shape and may be arrangedin any appropriate pattern. Alternatively, the holes may be formed inother shapes. For example, FIGS. 27-28 show an illustrative embodimentof a cap 1802 that has similarities to the embodiment of FIGS. 22-26 inwhich the holes 1818 are spaced farther from sidewall 1812 and aregenerally rectangular in profile. The holes may be formed with aconstant cross-section as illustrated in FIGS. 24-25 and 28, or theholes may have a different cross-section. For example, the holes mayhave a conical or pyramid shape such that the opening 1728 adjacent tothe distal surface 1714, 1814 of the cavity 1710, 1810 has a greatercross-sectional area than the bottom 1724 of the hole 1718.Alternatively, the hole may have an undercut such that the openingadjacent to the distal surface 1714, 1814 of the cavity 1710, 1810 has asmaller cross-sectional area than the bottom 1724 of the hole 1718. Theshape or geometry of the hole may be such that the surface tension(cohesion and adhesion) of the disinfecting solution is held inside thehole below the distal surface 1714, 1814 without the need for a cover orother retaining mechanism.

In one embodiment, the disinfecting solution in the cap fills theindividual cavities 1718 as well as at least a portion of the maincavity 1710. Applicants have surprisingly found that a cap having thisconfiguration, namely multiple cavities in the bottom surface inconjunction with a main cavity, causes the cap to significantly retain agreater volume of solution, particularly when inverted than is achievedwith a cap having a single main cavity portion. This allows the cap tobe inverted when being installed on a port while still retaining asufficient volume of solution. Such a cap retains sufficient solutioneven when the cap is shaken. This result is found both in caps thatemploy internal threads and in caps that do not have threads but ratheruse a constant diameter cylindrical sidewall cavity that engages theport by a friction fit.

In tests performed using a cap having a honeycomb depth of 2.5 mm,initial testing shows honeycomb structure retains 50% more IPA whileinverted than a cap without honeycomb or some other fluid retentionmechanism. In additions, the honeycomb was able to retain 70% of theinverted IPA following vigorous shaking.

FIGS. 29-32 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap includes an open proximal end 1904and a closed distal end 1906. The cap 1902 may include ribs 1926 formedon an exterior surface to provide easier handling and twisting of thecap by a healthcare worker. The ribs may extend parallel to a centralaxis of the cap, as illustrated, or may have another configuration.Alternatively, other knurling, texturing, finger shaped or grip elementsmay be provided.

The proximal end has an opening 1908 that provides access to a cavity1910. The cavity 1910 has a generally cylindrical sidewall 1912 anddistal or bottom surface 1914. Threads 1916 may be formed on thesidewall in order to engage with the threads of a site to be cleaned andto retain the cap on the site. The threads may extend completely aroundthe internal circumference of the inner cavity, they may extendpartially around, or they may extend greater than once around the entireinternal circumference.

One or more depressions, cavities or holes 1918 are formed extendinginto the cap from the distal surface 1914 of the cavity 1910. Theseholes 1918 are at least partially filled with and serve as reservoirs toretain a disinfecting solution such as liquid or gel ISA. The holes 1918may be generally cylindrical in shape and may be arranged in anyappropriate pattern. Alternatively, the holes may be formed in othershapes.

The holes may be formed with a constant cross-section as illustrated inFIGS. 31-32, or the holes may have a different cross-section. Forexample, the holes may have a conical or pyramid shape such that theopening 1928 adjacent to the distal surface 1914 of the cavity 1910 hasa greater cross-sectional area than the bottom 1924 of the hole 1918.Alternatively, the hole may have an undercut such that the opening 1928adjacent to the distal surface 1914 of the cavity 1910 has a smallercross-sectional area than the bottom 1924 of the hole 1918. The shape orgeometry of the hole may be such that the surface tension (cohesion andadhesion) of the disinfecting solution is held inside the hole below thedistal surface 1914 without the need for a cover or other retainingmechanism when the cap is in use.

However, as illustrated in FIG. 36, the cap may include a peelable lid1950 or other packaging. A portion 1952 of the lid 1950 extends into thecavity 1910 of the cap 1902. An inside surface of the extending portion1952 of the lid may seal against the bottom surface of the cavity 1910to retain the disinfecting solution in the holes until the cap is used.

As shown in FIG. 33, the cap 1902 may be attached to the threaded femaleport of a Y-site 1930. The female port of the Y-site is inserted intothe cavity 1910 of the cap. Threads 1932 formed on an outside diameterof the female port 1930 engage with the interior threads 1916, securingthe cap to the port.

When inserted into the cap, the end surface 1934 of the site may come incontact with the distal surface 1914 of the cavity 1910 such that thesite is wetted by the disinfecting solution. As the face 1934 of theconnector engages the bottom surface 1914 of the cavity 1910, the bottomsurface 1914 and hole openings 1928 are distorted and disinfectingsolution releases from the holes 1918 as the holes deform and lose theirfull volume. The material of the entire cap or of only a sectionsurrounding the holes 1918 at the bottom of the cavity 1910 may be softor hard plastic, such as polypropylene (PP) or santoprene or otherthermoplastic elastomers (TPE). Alternatively, the surface of the sitemay remain spaced from the distal surface such that disinfecting isprovided by disinfecting solution vapor contained within the cap.

FIGS. 34-35 show an illustrative embodiment of a cap 2002 that hassimilarities to the embodiment of FIGS. 29-33 in which the holes 2018are formed as a honeycomb 2048 rather than as individual cavities.

FIGS. 40-42 show a further illustrative embodiment of a cap 2802 thathas similarities to the embodiment of FIGS. 34-35. In this exemplaryembodiment, the cap includes an open proximal end 2804 and a closeddistal end 2806. The cap 2802 may include ribs 2826 formed on anexterior surface to provide easier handling and twisting of the cap by ahealthcare worker. The ribs may extend parallel to a central axis of thecap, as illustrated, or may have another configuration. Alternatively,other knurling, texturing, finger shaped or grip elements may beprovided.

The proximal end has an opening 2808 that provides access to a cavity2810. The cavity 2810 has a generally cylindrical sidewall 2812 anddistal or bottom surface 2814. Threads 2816 may be formed on thesidewall in order to engage with the threads of a site to be cleaned andto retain the cap on the site. The threads may extend completely aroundthe internal circumference of the inner cavity, they may extendpartially around, or they may extend greater than once around the entireinternal circumference. In the illustrative embodiment, the threads areshown extending up to the surface of the proximal end 2804 of the cap.

Hexagonal cavities or holes 2818 similar to a honeycomb are formedextending into the cap from the distal surface 2814 of the cavity 2810.These holes 2818 are at least partially filled with and serve asreservoirs to retain a disinfecting solution such as liquid or gel ISA.

The holes may be formed with a constant cross-section as illustrated inFIGS. 40-42, or the holes may have a varying cross-section. For example,the holes may have a conical or hexagonal-pyramid shape such that theopening 2828 adjacent to the distal surface 2814 of the cavity 2810 hasa greater cross-sectional area than the bottom 2824 of the hole 2818.Alternatively, the hole may have an undercut such that the opening 2828adjacent to the distal surface 2814 of the cavity 2810 has a smallercross-sectional area than the bottom 2824 of the hole 2818. The shape orgeometry of the hole may be such that the surface tension (cohesion andadhesion) of the disinfecting solution is held inside the hole below thedistal surface 2814 without the need for a cover or other retainingmechanism when the cap is in use.

FIGS. 37-39 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 2102 includes a lanyard 2104 thatcan be used to hang or otherwise attaché the cap to the port or accesssite to be cleaned. The lanyard has a loop 2106 through which the portcan be inserted. The cap may include two cap portions 2108, 2110 suchthat the cap can be used twice. Each cap portion has a generallycylindrical side wall 2112, and open end 2114 and a closed end 2116. Thecaps are position back-to-back such that the closed end 2116 is shared.The cap 2102 is removed from any packaging, and the first cap portion2108 is applied to the port to be cleaned. Even when removed from theinitial packaging, the second cap portion 2110 includes a sealed lid2118. When the healthcare worker uses the cap for a second time, the lid2118 is removed, and the second cap portion 2110 is applied to the portto be cleaned.

FIGS. 43-45 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 2402 may be molded from PP oranother appropriate plastic or other material. The cap includes anopening 2404 with a peripheral surface 2406 surrounding the opening. Theopening 2404 provides access to a cavity 2408.

The cap 2402 may have a generally square cross-section or may includeribs formed on an exterior surface to provide easier handling andtwisting of the cap by a healthcare worker. The ribs may extend parallelto a central axis of the cap or may have another configuration.Alternatively, other knurling, texturing, finger shaped or grip elementsmay be provided.

The cavity 2408 has a generally cylindrical sidewall 2412 and distal orbottom surface 2414. Retention elements 2410 extend from the interiorsurface 2412. In various embodiments, the retention elements may beformed in a resilient manner such that the cap can be pushed onto theport. As the threads of the port are pushed past each retention element,that element allows the thread to pass and then rebounds into a positionin which the retention element engages the thread and retains the cap.Alternatively, the cap may be screwed onto the port such that theretention elements engage the threads.

One of ordinary skill in the art would understand that the retainingelements 2410 could be arrange in any number of possible patterns,including, among others, in columns, rows a spiral pattern or a spacedmatrix. Alternatively, threads may be formed on the sidewall in order toengage with the threads of a site to be cleaned and to retain the cap onthe site.

The cylindrical sidewall may have a constant diameter along alongitudinal axis of the cap or the diameter may increase along thelongitudinal axis such that the diameter of the sidewall is greater atthe proximal end than the diameter of the sidewall at the distal end ator near the bottom surface 2414 in one embodiment. In another embodimentthe diameter may decrease along the longitudinal axis such that thediameter of the sidewall is smaller at the proximal end than thediameter of the sidewall at the distal end at or near the bottom surface2414.

The cap 2402 may include an aperture 2416 adjacent the bottom or distalend of the cap. The aperture may be sized to accept the thumb pad 2418attached to the plunger actuating shaft 2420 of a syringe (not shown).The bottom surface 2424 enclosing the aperture 2416 may include a slot2422 that is of an appropriate size to accommodate a rib 2426 of thesyringe plunger shaft 2420.

An absorbent material 2430 may be positioned inside the cavity 2408. Theabsorbent material may be infused with a disinfecting solution.Alternatively, the disinfecting solution may be present in the cavitywithout the use of an absorbent material. The cap 2402 may include apeelable lid 2428 that is sealed to the top surface 2406 of the cap inorder to retain the disinfecting solution within the cap cavity 2408,thereby preventing the disinfecting solution from leaking or evaporatingout from the cap 2402.

FIG. 46 shows an illustrative disinfecting cap in accordance withembodiments of the invention. In this embodiment, the cap 2502 includesresilient fingers 2516 extending from a bottom surface 2524 of the cap.One or more slots 2522 may extend vertically between the resilientfingers 2516 so that the fingers can flex outward to accommodate thethumb pad 2518 attached to the plunger actuating shaft 2520 of a syringe2532. The fingers 2516 may include a notch or groove 2534 in which thethumb pad seats when the cap is installed. In the illustratedembodiment, the opening 2504 of the cap is positioned on the distal end2536 of the cap away from the syringe 2532.

FIG. 47 shows an illustrative disinfecting cap in accordance withembodiments of the invention. In this embodiment, the cap 2602 may beformed of a soft or flexible material. The cap includes a lip 2616 thatis stretched to extend around at least a portion of the diameter of thethumb pad 2618 attached to the plunger actuating shaft 2620 of a syringe(not shown). The cap 2602 includes a cavity 2608 having an opening 2604and a closed end 2614. In the illustrated embodiment, a top surface 2606of the cap surrounding the opening 2604 is positioned adjacent thesurface of the thumb pad 2618. In this manner, the thumb pad may act toseal the cavity 2608 in order to retain the disinfecting solution withinthe cap cavity.

In an alternative embodiment, as illustrated in FIGS. 48-49, the cap2702 may include a clip 2716. The clip may include resilient arms 2718that are sized to releasably engage the barrel 2734 of a syringe 2732.

An absorbent material 2730 may be positioned inside the cavity 2408. Theabsorbent material may be infused with a disinfecting solution.Alternatively, the disinfecting solution may be present in the cavitywithout the use of an absorbent material. The cap 2702 may include apeelable lid 2728 that is sealed to the top surface 2706 of the cap inorder to retain the disinfecting solution within the cap cavity 2708,thereby preventing the disinfecting solution from leaking or evaporatingout from the cap 2702.

FIGS. 50-53 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 2202 is molded from PU and may bereaction injection molded from PU foam into the final shape. The moldedfoam 2240 may include a skin 2242 that is resistant to IPA or otherdisinfecting solutions. The cap includes an open proximal end 2204 and aclosed distal end 2206. The cap 2202 may include ribs 2226 formed on anexterior surface to provide easier handling and twisting of the cap by ahealthcare worker. The ribs may extend parallel to a central axis of thecap, as illustrated, or may have another configuration. Alternatively,other knurling, texturing, finger shaped or grip elements may beprovided.

The proximal end has an opening 2208 that provides access to a cavity2210. The cavity 2210 has a generally cylindrical sidewall 2212 anddistal or bottom surface 2214. The cylindrical sidewall 2212 may have aconstant diameter along a longitudinal axis of the cap or the diametermay increase along the longitudinal axis such that the diameter of thesidewall is greater at the distal end than the diameter of the sidewallat the proximal end at or near the bottom surface 2214 in oneembodiment. In another embodiment the diameter may decrease along thelongitudinal axis such that the diameter of the sidewall is smaller atthe distal end than the diameter of the sidewall at the proximal end ator near the bottom surface 2214.

Embodiments of the cap may include a valve 2230. The valve may be a“duckbill,” diaphragm or other type of self-sealing valve. As shown inthe illustrative embodiment, the valve 2230 includes a lip 2232 thatextends over a top surface 2234 of the cavity sidewall 2236. Thesidewall 2236 may include a counterbore 2238 or recess to accommodatethe lip 2232 such that a proximal surface of the lip is flush with aproximal surface of the cap. A portion 2244 of the valve 2230 extendsdistally from the lip 2232 along the inside diameter 2212 of the cavity2210. Starting at a position below the proximal surface of the cap, twogenerally planar portions 2246 of the valve extend distally at arelative angle so as to meet at an acute angle 2248. A slit 2250 isformed at the intersection of the two planar portions 2246.

When a healthcare worker inserts the port to be cleaned into the cap,the end of the port enters through the valve and is exposed to thedisinfecting solution. The valve secures the end of the port in thecavity once the port passes through the slit 2250. A portion of thecavity 2210 may be filled with IPA or another disinfecting substance inliquid or gel form. Alternatively, at least a portion of the cavity maybe filled with a foam, such as an open cell PU foam. The foam may beinfused with a disinfecting substance. The valve may operate to securethe cap to the port and may also prevent or reduce leaking ofdisinfecting solution out of the cap.

The cap 2202 may include a peelable lid 2220 that is sealed to the skin1742 of the cap in order to retain the disinfecting solution within thecap cavity 2210, thereby preventing the disinfecting solution fromleaking or evaporating out from the cap 2202.

FIGS. 55-57 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 2302 includes a first engagingportion 2330 and a second reservoir portion 2370. The engaging portion2330 includes side a generally cylindrical sidewall 2338. The engagingportion includes an open proximal end 2334 and an open distal end 2336and encompasses a cavity 2342. Threads 2340 may be formed on thesidewall in order to engage with the threads of a site to be cleaned andto retain the cap on the site. The cylindrical sidewall may have aconstant diameter along a longitudinal axis of the cap or the diametermay increase along the longitudinal axis such that the diameter of thesidewall is greater at the proximal end 2334 than the diameter of thesidewall at the distal end 2336. In another embodiment the diameter maydecrease along the longitudinal axis such that the diameter of thesidewall is smaller at the proximal end 2334 than the diameter of thesidewall at the distal end 2336.

The cap 2302 may include ribs (not shown) formed on an exterior surfaceto provide easier handling and twisting of the cap by a healthcareworker. The ribs may extend parallel to a central axis of the cap, asillustrated, or may have another configuration. Alternatively, otherknurling, texturing, finger shaped or grip elements may be provided.

The engaging portion 2330 includes a diaphragm valve 2344 that coversthe distal end 2336 of the cavity 2342. The valve may cover a distal end2346 of sidewall 2338 as well as the open end 2336 of the cavity 2342. Aportion 2348 of the diaphragm valve 2344 may extend beyond the openingalong an outside surface 2350 of sidewall 2338. The valve may be moldedover the sides and open end of the engaging portion. The diaphragm valve2344 includes a slit 2352. A female port or other access site is pushedthrough the slit 2350 into the cavity 2342 as the threads 2340 of thecavity engage the threads of the port. Alternatively, the diaphragmvalve may secure the end of the port in the cavity once the port passesthrough the slit.

The cap 2302 further includes a reservoir portion 2370. The reservoirportion has an open proximal end 2372 and a closed distal end 2374. Agenerally cylindrical sidewall 2378 encompasses a cavity 2376. Thereservoir portion may be sonically welded or otherwise attached to theengaging portion. A portion of the cavity 2376 may be filled with IPA oranother disinfecting substance in liquid or gel form. Alternatively, atleast a portion of the cavity may be filled with a foam, such as an opencell PU foam. The foam may be infused with a disinfecting substance.Accordingly, as a female port or other access site is pushed through theslit 2352 of the engaging portion 2330 into the cavity 2376 of thereservoir portion 2370, the port is exposed to the disinfectingsubstance.

FIGS. 58-60 show an illustrative disinfecting cap in accordance withembodiments of the invention. The cap 2902 may be molded from PP.Alternatively, the cap may be molded from PU and may be reactioninjection molded from PU foam into the final shape. The molded foam mayinclude a skin that is resistant to IPA or other disinfecting solutions.The cap 2902 includes an open proximal end 2904 and a closed distal end2906. The cap may include ribs 2926 formed on an exterior surface toprovide easier handling and twisting of the cap by a healthcare worker.The ribs may extend parallel to a central axis of the cap, asillustrated, or may have another configuration. Alternatively, otherknurling, texturing, finger shaped or grip elements may be provided.

The proximal end has an opening 2908 that provides access to a cavity2910. The cavity 2910 has a generally cylindrical sidewall 2912 anddistal or bottom surface 2914. Threads may be formed on the sidewall inorder to engage with the threads of a site to be cleaned and to retainthe cap on the site. The cylindrical sidewall may have a constantdiameter along a longitudinal axis of the cap or the diameter mayincrease along the longitudinal axis such that the diameter of thesidewall is greater at the proximal end than the diameter of thesidewall at the distal end at or near the bottom surface 2914 in oneembodiment. In another embodiment the diameter may decrease along thelongitudinal axis such that the diameter of the sidewall is smaller atthe distal end than the diameter of the sidewall at the proximal end ator near the bottom surface 2914.

The cap 2902 may also include a separating disc or screen 2918. Theillustrative screen 2918 has a generally cylindrical disc/flat circularshape with an outside diameter 2920 that corresponds across at leastpart of its perimeter to the sidewall 2912 of the cavity 2910. Thescreen 2918 divides the cavity 2910 into two portions, a proximalportion 2922 adjacent to the opening 2908 and a distal portion 2924adjacent to the bottom surface 2914 of the cavity. The distal cavity2924 may be filled at least partially with a disinfecting solution.

The screen 2918 may have one or more through holes 2928. The holes 2928may be generally cylindrical in shape and may be arranged in anyappropriate pattern. Alternatively, the holes may be formed in othershapes. The holes may be formed with a constant cross-section asillustrated in FIGS. 58-60, or the holes may have a differentcross-section. For example, the holes may have a conical or pyramidshape.

The sidewall 2912 of the cavity 2910 may include one or more slots 2930.The slots extend parallel to a longitudinal axis of the cap. Ridges orarms 2932 extend from the outside diameter 2920 of the screen 2918.These arms 2932 engage with the slots 2930 in the cavity diameter andallow the screen 2918 to slide longitudinally within the cavity 2910.The arms 2932 may extend longitudinally above a top surface 2934 of thescreen 2918.

FIGS. 58 and 60 show the cap prior to insertion of the female port 2036of the Y-site 2038 into the cap. The screen is positioned adjacent theopen end 2904 of the cap such that the arms 2932 are parallel with orbelow the top surface 2903 of the cap.

FIGS. 61-62 show the cap 2902 at the point that the female port 2934first makes contact with the cap. In the illustrative embodiment,threads 2940 formed on an outside diameter of the female port or thedistal surface 2942 of the port 2934 contact the arms 2932 of the screen2918. The screen top surface 2934 is spaced apart from the top surface2903 of the cap by a first distance 2944. At this point, the distalportion 2924 of the cavity 2910 is at least partially filled with adisinfecting solution while the proximal portion 2922 of the cavity doesnot include any disinfecting solution.

FIGS. 63-64 show the cap 2902 at a point that the female port 2934 hasbeen pushed partially within the cap. The screen top surface 2934 isspaced apart from the top surface 2903 of the cap by a second, greaterdistance 2946. At this point, the distal portion 2924 of the cavity 2910remains at least partially filled with a disinfecting solution, but atleast a portion of the disinfecting solution has been forced through theholes 2928 into the proximal portion 2922 of the cavity. Thedisinfecting solution wets and disinfects the surface of the female port2934.

FIGS. 65-66 show the cap 2902 at a point that the female port 2934 hasbeen fully pushed into the cap. The screen top surface 2934 is spacedapart from the top surface 2903 of the cap by a third, greater distance2948. At this point, the distal portion 2924 of the cavity 2910 may becompletely collapsed as shown in the illustrative embodiment.Alternatively, the distal portion of the cavity may retain some volumethat is at least partially filled with a disinfecting solution but witha significant portion of the disinfecting solution having been forcedthrough the holes 2928 into the proximal portion 2922 of the cavity. Theinside diameter 2912 of the cavity 2910 may engage the threads 2940 ofthe female port 2934 with a friction fit in order to retain the cap onthe port.

As the port 2934 is inserted into the cap, it forces the screen 2918into the distal cavity portion 2924, and disinfecting solution is forcedthrough holes 2918 into the proximal cavity portion 2922 where it wetsand disinfects the port. The disinfecting fluid may flow through theholes such that it flows along the sidewall 2912 of the cavity and ontothe port. Alternatively, the speed of inserting the port may be suchthat the disinfecting fluid is forced through the holes 2918 withsufficient force to cause the disinfecting fluid to spray onto and coatthe port surface.

The embodiments shown in FIGS. 58-66 provide examples in which thescreen 2918 has a certain thickness between the top surface 2934 and abottom surface. In alternative embodiments of the invention, the screenmay have a different thickness that is thinner or thicker than theexemplary embodiment shown. In view of the disclosure of thisapplication, one of ordinary skill in the art would understand that thethickness of the screen in combination with the size and shape of theholes 2928 would affect the disinfecting fluid flows or sprays onto theport surface.

The cap 2902 may include a peelable lid that is sealed to a top surface2903 of the cap in order to retain the disinfecting solution within thecap cavity 2910, thereby preventing the disinfecting solution fromleaking or evaporating out from the cap 2902.

Although a few embodiments have been described in detail above, othermodifications are possible. For instance, any of the embodimentsdescribed above may be sized and scaled for a particular medicalimplement, such as a stethoscope or otoscope. Other embodiments may bewithin the scope of the following claims.

This application provides a description of various implementations andembodiments of a device for cleaning medical implements. The variousembodiments have been described as having a variety of features. It willbe understood by one of ordinary skill in the art that features of thevarious embodiments are intended to be interchangeable, and featuresdescribed in the context of one embodiment may be implemented inconjunction with a device having the features and structure of anotherembodiment.

What is claimed is:
 1. A disinfecting cap comprising: an open end; aclosed end; an exterior surface comprising: a peripheral surfaceadjacent the open end, a bottom surface adjacent the closed end, and aside surface extending between the open end and the closed end; a cavityadjacent to the open end to receive an access site, the cavitycomprising a bottom surface and sidewall; a disinfecting solution atleast partially filling the cavity; first and second fingers extendingfrom the exterior surface bottom surface in a direction parallel to theexterior surface side surface; and a slot extending between the firstand second finger; wherein the exterior surface of the disinfecting capis removeably attachable to a syringe and the first and second fingersflex outward to accommodate a thumb pad of the syringe.
 2. Thedisinfecting cap of claim 1, wherein at least a portion of the cap ismolded from a polyurethane foam.
 3. The disinfecting cap of claim 1,wherein at least a portion of the cap is molded from a thermoplasticelastomer.
 4. The disinfecting cap of claim 1, wherein the cavitysidewall is cylindrically shaped.
 5. The disinfecting cap of claim 1,wherein the disinfecting solution comprises isopropyl alcohol.
 6. Thedisinfecting cap of claim 1, wherein the disinfecting solution compriseschlorhexidine gluconate.
 7. The disinfecting cap and syringe system ofclaim 1, wherein the slot extending between the first and second fingersencompasses a rib of a plunger of the syringe.
 8. A disinfecting cap andsyringe system comprising: a syringe comprising: a plunger having aplunger shaft with a rib and a thumb pad; and a barrel; and adisinfecting cap comprising: an open end; a closed end; an exteriorsurface comprising: a peripheral surface adjacent the open end, a bottomsurface adjacent the closed end, and a side surface extending betweenthe open end and the closed end; a cavity adjacent to the open end toreceive an access site, the cavity comprising a bottom surface andsidewall; first and second fingers extending from the exterior surfacebottom surface in a direction parallel to the exterior surface sidesurface, the first and second fingers comprising a groove; and a slotextending between the first and second finger; wherein the exteriorsurface of the disinfecting cap is removeably attached to the syringe,the first and second fingers flex outward to accommodate a thumb pad ofthe syringe, the plunger shaft rib is positioned within the slotextending between the first and second fingers, and the plunger thumbpad engages the first and second finger groove.
 9. The disinfecting capand syringe system of claim 8 wherein the disinfecting cap exteriorsurface comprising a grip element.
 10. The disinfecting cap and syringesystem of claim 8, wherein the disinfecting cap cavity comprises aretention element extending from the cavity sidewall.
 11. Thedisinfecting cap and syringe system of claim 8, wherein the disinfectingcap cavity comprises an absorbent material.
 12. The disinfecting cap andsyringe system of claim 8, wherein the disinfecting cap comprises apeelable lid that is sealed to the disinfecting cap exterior surfaceperipheral surface.
 13. The disinfecting cap and syringe system of claim8, wherein the first and second fingers flex outward to accommodate athumb pad of the syringe.
 14. The disinfecting cap and syringe system ofclaim 8, wherein and outside surface of the first and second fingers iscontinuous with the exterior surface side surface.